Reduction in crystallization time of Sb:Te films through addition of Bi

Simpson, Robert E.; Hewak, D.W.; Fons, Paul; Tominaga, Junji; Guérin, Samuel; Hayden, Brian E.

doi:10.1063/1.2901161

Cited by 24 publications

(12 citation statements)

References 16 publications

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“…Wang and co‐workers found that doping GST with 3.3 at% Bi improved the crystallization speed and lowered the crystallization temperature, which was correlated with a reduction in the crystallization activation energy. Simpson et al likewise found that Bi doping decreased the crystallization time in Sb 2 Te 8 , although it was noted that, in contrast to the work found elsewhere, the doping appeared to have little effect on the activation energy. It was speculated that the faster crystallization may be due to an increase in free volume in the amorphous material, and a corresponding decrease in viscosity, facilitating easier atomic diffusion during crystallization .…”

Section: Introductionmentioning

confidence: 87%

“…In spite of these caveats, the present simulations do seem to reproduce the trend in experimental growth‐rate enhancement imparted by Bi doping. To investigate the mechanism proposed by Simpson et al, we studied the effect of the dopant on the compressibility of the amorphous and crystalline models. To do this, the volume of each model was changed by ±500 Å 3 (corresponding to volume reductions and expansions of up to ≈10%) in eleven equal steps, with the atomic positions being scaled accordingly, and the total energy was obtained after ionic relaxation.…”

Section: Crystallization Dynamicsmentioning

confidence: 99%

“…Bi has been shown to have a range of interesting effects, both on GST hosts, and also on other PCM systems . Wang and co‐workers found that doping GST with 3.3 at% Bi improved the crystallization speed and lowered the crystallization temperature, which was correlated with a reduction in the crystallization activation energy.…”

Section: Introductionmentioning

confidence: 99%

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Atomistic Origin of the Enhanced Crystallization Speed and n‐Type Conductivity in Bi‐doped Ge‐Sb‐Te Phase‐Change Materials

Skelton

Pallipurath

Lee

et al. 2014

Adv Funct Materials

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Phase‐change alloys are the functional materials at the heart of an emerging digital‐storage technology. The GeTe‐Sb2Te3 pseudo‐binary systems, in particular the composition Ge2Sb2Te5 (GST), are one of a handful of materials which meet the unique requirements of a stable amorphous phase, rapid amorphous‐to‐crystalline phase transition, and significant contrasts in optical and electrical properties between material states. The properties of GST can be optimized by doping with p‐block elements, of which Bi has interesting effects on the crystallization kinetics and electrical properties. A comprehensive simulational study of Bi‐doped GST is carried out, looking at trends in behavior and properties as a function of dopant concentration. The results reveal how Bi integrates into the host matrix, and provide insight into its enhancement of the crystallization speed. A straightforward explanation is proposed for the reversal of the charge‐carrier sign beyond a critical doping threshold. The effect of Bi on the optical properties of GST is also investigated. The microscopic insight from this study may assist in the future selection of dopants to optimize the phase‐change properties of GST, and also of other PCMs, and the general methods employed in this work should be applicable to the study of related materials, for example, doped chalcogenide glasses.

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Section: Introductionmentioning

confidence: 87%

Section: Crystallization Dynamicsmentioning

confidence: 99%

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Atomistic Origin of the Enhanced Crystallization Speed and n‐Type Conductivity in Bi‐doped Ge‐Sb‐Te Phase‐Change Materials

Skelton

Pallipurath

Lee

et al. 2014

Adv Funct Materials

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“…It is also shown that Bi doping into Sb 80 Te 20 can further reduce crystallization time but lead to a low crystallization temperature or poor archival stability [4]. In contrast, by adding Ge, Ag, In, and Ga into Sb 70 Te 30 or Sb 80 Te 20 , a good archival stability is achieved, but the crystallization rate slows [1,2,5].…”

Section: Introductionmentioning

confidence: 99%

Effect of periodic number of [Si/Sb80Te20] x multilayer film on its laser-induced crystallization studied by coherent phonon spectroscopy

et al. 2012

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The periodic number dependence of the femtosecond laser-induced crystallization threshold of [Si(5nm)/Sb80Te20(5nm)]x nanocomposite multilayer films has been investigated by coherent phonon spectroscopy. Coherent optical phonon spectra show that femtosecond laser-irradiated crystallization threshold of the multilayer films relies obviously on the periodic number of the multilayer films and decreases with the increasing periodic number. The mechanism of the periodic number dependence is also studied. Possible mechanisms of reflectivity and thermal conductivity losses as well as the effect of the glass substrate are ruled out, while the remaining superlattice structure effect is ascribed to be responsible for the periodic number dependence. The sheet resistance of multilayer films versus a lattice temperature is measured and shows a similar periodic number dependence with one of the laser irradiation crystallization power threshold. In addition, the periodic number dependence of the crystallization temperature can be fitted well with an experiential formula obtained by considering coupling exchange interactions between adjacent layers in a superlattice. Those results provide us with the evidence to support our viewpoint. Our results show that the periodic number of multilayer films may become another controllable parameter in the design and parameter optimization of multilayer phase change films.

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“…In contrast to conventional static testers, 6 the system monitors the transmission of light through the sample with nanosecond time resolution. To ensure that the probe beam measures the center of the pump beam's spot both laser beams were coupled into a single mode optical fiber.…”

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confidence: 99%

Non-melting super-resolution near-field apertures in Sb–Te alloys

Simpson

Fons

Wang

et al. 2010

Applied Physics Letters

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Structure of the optical phase change memory alloy, Ag-V-In-Sb-Te, determined by optical spectroscopy and electron diffractionThe super-resolution near-field structure permits the formation of short-lived subdiffraction limit apertures that channel electromagnetic energy at the aperture boundary. This effect is commonly observed when a laser is focused onto a thin film of Sb based material. The aperture formation within Sb, Sb 2 Te 3 , Sb 2 Te, and SbTe is investigated by time resolved optical pump-probe techniques and found to occur without melting. Ab initio modeling has shown a threshold-like change in the optical properties below the melting temperature which leads to the formation of a near-field aperture. This threshold is shown to be a consequence of thermally induced misalignment of p-type bonding.

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Reduction in crystallization time of Sb:Te films through addition of Bi

Cited by 24 publications

References 16 publications

Atomistic Origin of the Enhanced Crystallization Speed and n‐Type Conductivity in Bi‐doped Ge‐Sb‐Te Phase‐Change Materials

Atomistic Origin of the Enhanced Crystallization Speed and n‐Type Conductivity in Bi‐doped Ge‐Sb‐Te Phase‐Change Materials

Effect of periodic number of [Si/Sb80Te20] x multilayer film on its laser-induced crystallization studied by coherent phonon spectroscopy

Non-melting super-resolution near-field apertures in Sb–Te alloys

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